Tantalum pellet system and methods of making and using the same

ABSTRACT

1. A TANTALUM PELLET SYSTEM COMPRISING A BAR OF AN ALLOY CONSISTING ESSENTIALLY OF ALUMINUM AND FROM ABOUT ONE TO SIX PERCENT OF MAGNESIUM BY WEIGHT; AND A PLURALITY OF SINTERED TANTALUM PELLETS, EACH SAID PELLET HAVING A TANTALUM WIRE LEAD EXTENDING THEREFROM, EACH SAID LEAD BEING WELDED TO SAID BAR, EACH SAID LEAD LYING ESSENTIALLY AT RIGHT ANGLES TO THE MAJOR AXIS OF SAID BAR, ALL SAID LEADS LYING ESSENTIALLY IN ONE PLANE AND THE CLOSEST SEPARATION BETWEEN EACH SAID PELLET AND SAID BAR BEING 3/8 INCH OR LESS.

1974 w. J. BERNARD 3,343,492

TANTALUM PELLET SYSTEM AND METHODS OF IAKING AND USIiIG THE SAME Filed lay 18, 1973 United States Patent US. Cl. 204- 7 Claims ABSTRACT OF THE DISCLOSURE A pellet system for use in the manufacture of solid electrolyte electrolytic capacitors comprises a bar and a plurality of sintered tantalum pellets, each having a short tantalum anode wire lead such that the closest separation between a pellet and the bar is no greater than inch. Each wire lead is welded to the bar such that the pellets may be registered and held properly submersed in liquid processing baths. The material of the bar is a low cost aluminum magnesium alloy that readily forms a dielectric oxide film and that does not warp during the formation, pyrolysis, or other capacitor manufacturing processes.

BACKGROUND OF THE INVENTION This invention relates to a tantalum pellet system and more particularly to a tantalum pellet system for use in manufacturing capacitors. Pellets in such a system are formed by compressing and sintering tantalum particles that are thereafter treated and processed so as to form a solid tantalum capacitor from each pellet.

A tantalum pellet carrier is normally employed throughout most of such capacitor manufacturing processes. The system is typically made by having the anode wire lead to each such pellet lap welded to a horizontal metal bar such that a multiplicity of pellets hang downward from the bar. Typically the bar is made of stainless steel.

Many of the process steps involve the immersion of the pellets into a liquid. A typical process is one such as that described by Millard in US. Letters Patent 2,936,514. The pellet carrier is usually lowered over the liquid such that the pellets are completely immersed with the bar being held by a fixture that registers the pellet carrier relative to the liquid container. The bar is thus not immersed. Immersion of the bar during the oxide forming stepis especially undesirable since this would cause heavy current to flow between the electrolyte and the large surface area of the bar, paralleling and making difficult the controL of the current to the pellets. Therefore the tantalum wire leads must be long enough to insure complete immersion of the pellets and no immersion of the bar, and this is obviously a function of the degree of control of the liquid level that is achieved.

Tantalum wire is expensive, costing on the order of fifty dollars a pound. Significant cost savings can be realized by reducing the length of the tantalum wire leads. However, the shorter the tantalum wires become, the more likely the pellet carrier bar is wetted by the electrolyte in regions near the point of the wire welds. This may occur as a result of electrolyte vapor condensation, Splatter, or wicking or a combination thereof. When the bar of the pellet carrier is made of tantalum or another valve metal that forms a non-porous and self sealing dielectric oxide film, the small leakage currents flowing to the bar may not adversely affect the control of the pellet oxide forming process; but when cheaper bars are made, for example of stainless steel, electrochemical reactions on the bar can permit very large currents to flow indefinitely, and the pellet forming process control thereby becomes seriously degraded. The reactions which can occur include oxygen evolution, the formation of conducting compounds, and anodic dissolution, the products of which can contaminate the electrolyte and degrade the quality of the capacitors.

Aluminum bars would seem to be a good candidate material to solve these problems. Aluminum is the least expensive and most readily available of the valve metals. However, aluminum bars soften and warp at the high temperatures employed for the pyrolosis of the manganous salts. Such warpage results in non-uniform immersion of the pellets in subsequent steps whereby for example the solid electrolyte may extend up a pellet wire further than did the oxide formation, causing an anode to cathode short.

Except for the expensive valve metals such as tantalum, there has heretofore been found no suitable material for making a pellet system bar that would accommodate short-wire pellets.

It is therefore an object of this invention to provide a pellet system having short wire leads.

It is a further object of this invention to provide a pellet system having a bar that forms a self-sealing oxide film and which does not warp.

It is a further object of this invention to provide a low cost pellet system that permits a significant reduction in the cost of manufacturing solid tantalum electrolytic capacitors.

These and other objects will become apparent in the following description of the prefer-red embodiments.

The aforementioned objects are satisfied by the present invention as Weil as by the invention of my copending application Ser. No. 361,688, filed concurrently herewith.

SUMMARY OF THE INVENTION A tantalum pellet system for use in the manufacture of solid tantalum capacitors comprises a metal bar and a plurality of sintered tantalum pellets each having a tantalum anode wire lead welded to the bar. The length of the lead between the bar and each pellet at their closest separation is no longer than The bar is an aluminum alloy having from about 1 to 6 percent magnesium by weight, and trace elements. The bar so made has a low lcost, and readily forms good dielectric oxide films, and will not warp during normal capacitor manufacturing processes including, formation, impregnation with manganous salts, pyrolysis, and application of the cathode electrode. This low cost bar material, advantageously having the aforementioned properties, permits the construction of a pellet system wherein the expensive wire leads may be made very short thus providing a further important economic advantage in the manufacture of solid tantalum capacitors.

In FIG. 1 is shown a tantalum pellet system according to a first preferred embodiment of this invention.

In FIG. 2 is shown a cross-sectional view of the system in FIG. 1 taken in section 2-2.

In FIG. 3 is shown a tantalum pellet system according to a second preferred embodiment of this invention.

In FIG. 4 is shown a cross-sectional view of the system in FIG. 3 taken in section 4-4.

In FIG. 5 is shown a cross-sectional view of a tantalum pellet system wherein the pellets serve as the anode electrode in an electrolytic cell.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Shown in FIG. 1 is a first preferred embodiment of the present invention. The metal bar 10 is made of an alloy composed of from about 1 to 6 percent magnesium, trace elements, and the remainder aluminum. Each of a multiplicity of sintered tantalum pellets 14, has a conventional tantalum anode wire lead 12. Each wire 12 is essentially at right angles to the main axis of the bar 10 and all such leads 12 are essentially in the same plane. The wire lead 12 from each pellet 14 is lap welded to the bar 10. Thus a tantalum pellet system is constructed wherein the pellets 14, the tantalum anode wires 12, and the bar 10, are all electrically as well as mechanically interconnected. In FIG. 2 is shown a cross-sectional view of the system of FIG. 1 taken in section 22. The weld 11 is made in a region between the overlapping top portion of the Wire lead 12 and the bottom portion of the bar 10. It is thus called a lap weld.

A second preferred embodiment is presented in FIG. 3, being similar to that of FIG. 1 except for a different manner of interconnecting the wire leads with the bar. The tantalum pellets 24 each have a conventional tan talum anode lead 22. The wire leads are butt welded to the bottom edge of the bar 10. FIG. 4 shows a crosssection of the system taken in section 4-4 as shown in FIG. 3. The Weld 21 joins the end of the wire lead 22 and the bar 10.

:In FIG. 5 is shown a third preferred embodiment of a tantalum pellet system for use in forming an oxide over the surfaces and within the interstices of the tantalum pellets by electrolysis. The bar 10, the pellets 14, the tantalum leads 12, and their interconnections are as has been described for the system of the first preferred embodiment. The bar has a projection at either end. The assembly comprised of the bar 10, leads 12, and pellets 14 is suspended by those projections resting on the rim of a tank 16 such that the pellets hang downward and are completely submersed in a liquid electrolyte 15. The tank 16 is of stainless steel. A power supply 18- is connected between the bar 10 and the tank 16, with the positive terminal connected to the bar 10. Thus, the power supply is connected to an electrolytic cell wherein the pellets 14 act as the anode electrode and the tank 16 acts as the cathode electrode. The power supply 16 is a conventional constant voltage supply having a current limit feature. When the system is first connected to the power supply, the resistance of the cell is very low and a high current tends to flow. However, the power supply voltage automatically drops so as to keep the initial current at a limit to which it has been adjusted, which for example may be on the order of l ampere for each 20 pellets. As the oxide grows, the resistance of the cell increases until the current is less than 1 ampere for example and the power supply provides the constant voltage to the cell during the rest of the oxide formation process step.

The electrolyte level is adjusted so that the pellets are completely submersed, and in fact the level may be so high as to encompass a portion of the bar with no deleterious effects on the pellet oxide forming process or the control thereof. It has been found that the best solutions for use as an electrolyte have a pH from between and 7. Specifically a 0.1% aqueous solution of ammonium dihydrogen phosphate (ADP), was successfully employed as the electrolyte in the making of experimental capacitors.

The alloy of which the bars and are made in the first, second and third preferred embodiments, forms an impervious dielectric oxide of substantially equal quality to that of a tantalum bar for effective use in a pellet system. Its strength is much greater than that of aluminum alone, and it does not exhibit any substantial warpage when exposed to temperature as high as 450 C. This material is readily available in large quantities, it being used extensively in the automobile industry.

A number of experimental pellet systems have been made acocrding to the description of the first preferred embodiment. The metal bar 10 is made of an alloy cornposed essentially of aluminum and about 2.5% magnesiurn by weight, and trace elements, namely Alloy 5252 as supplied by Reynolds Metals Company. See Alloy Digest published by Engineering Alloys Digest Inc., Upper Montclair, NJ. The bar 10 has the dimensions 10 inches long, inch wide and 0.032 inch thick. Tantalum pellets having tantalum wire leads of from 0.14 to .022 inches in diameter were uniformly spaced and lap welded to a side of the bar. The welds were made by a normal capacitor discharge type welded having one electrical connection to the bar and the other connection made through a standard maneuverable weld electrode. The length of tantalum lead overlapping the bar was about 4 inch. The length of tantalum lead between the pellet and the lower edge of the bar was about inch. The length of wire overlapping the bar should be no longer than necessary for reliably making the weld. About A; inch is adequate.

The experimental systems were then used in a complete solid tantalum capacitor manufacturing process. Simultaneously, a standard system having bars made of stainless steel Was used in a complete solid tantalum manufacturing process, so as to provide a control system for the experiments. The standard control system included pellets having tantalum wire leads of inch long, and a separation between bar and pellets of about inch. While the experimental systems used a substantially smaller quantity of costly tantalum than the standard system, no significant differences were observed in the quality of the resulting capacitors.

The aforementioned aluminum alloy bars possess far greater strength especially after exposure to the high capacitor processing temperatures, than pure aluminum. Their cost is about equal to or less than that of stainless steel, and far less than that of pure tantalum bars.

Concomitant with the economic benefit from use of a low cost aluminum alloy bar, as taught in this invention, is the cost savings that may be realized by keeping the tanalum wire leads short. It has been shown that at least /ii inch of tantalum wire can be saved by use of the tantalum pellet system of this invention in comparison with a standard system that employs non valve metal bars such as stainless steel. In 1972 Well over one hundred million solid tantalum capacitors were sold in this country and this rate appears to be strongly increasing. Based upon the 4 inch of tantalum Wire saving per capacitor and assuming the consumption rate of 1972, it is estimated that potential total dollar savings from the use of this invention would exceed one million dollars.

What is claimed is:

1. A tantalum pellet system comprising a bar of an alloy consisting essentially of aluminum and from about one to six percent of magnesium by weight; and a plurality of sintered tantalum pellets, each said pellet having a tantalum wire lead extending therefrom, each said lead being welded to said bar, each said lead lying essentially at right angles to the major axis of said bar, all said leads lying essentially in one plane and the closest separation between each said pellet and said bar being inch or less.

2. The tantalum pellet system of claim 1 wherein said alloy consists essentially of aluminum and about 2 /2 percent magnesium by weight.

3. The tantalum pellet system of claim 1 wherein said weld is a lap weld between each said lead and one side of said bar.

4. The tantalum pellet system of claim 1 wherein said weld is a butt weld between each said lead and a face of said bar.

5. The method of forming oxide films on the tantalum pellets of the system of claim 1 wherein said pellets are held by said bar and are completely submersed in a liquid electrolyte of an electrolytic cell, said pellets serving as the multiple anode electrodes of said cell.

6. A method of making a tantalum pellet system comprising the step of welding the wire lead from a tantalum pellet to a bar, said bar being made of an alloy consisting essentially of aluminum and from about one to six percent of magnesium by weight.

5 6 7. The method of claim 6 wherein said alloy consists 2,821,495 1/1958 Dulin 148-2191 essentially of aluminum and about 2 /2 percent mag- 2,113,937 4/ 1938 Fran ks l131l2 nesium by weight. 2,122,185 6 /1938 Smith 1131l2 References Cited UNITED STATES PATENTS 5 JOHN H. MACK, Prlmary Examiner 2,936514 5 0 Millard 29 570 A LANGEL, Assistant Examiner 3,573,566 4/1971 Fournier et al. 29570 2,830,698 4/1958 Coda et a1. 29 193.s US 3,445,731 5/1969 Saeki et a1. 29570 29-504, 570; 204286 3,055,098 9/1962 Bratkowski et al. 29-492 10 

1. A TANTALUM PELLET SYSTEM COMPRISING A BAR OF AN ALLOY CONSISTING ESSENTIALLY OF ALUMINUM AND FROM ABOUT ONE TO SIX PERCENT OF MAGNESIUM BY WEIGHT; AND A PLURALITY OF SINTERED TANTALUM PELLETS, EACH SAID PELLET HAVING A TANTALUM WIRE LEAD EXTENDING THEREFROM, EACH SAID LEAD BEING WELDED TO SAID BAR, EACH SAID LEAD LYING ESSENTIALLY AT RIGHT ANGLES TO THE MAJOR AXIS OF SAID BAR, ALL SAID LEADS LYING ESSENTIALLY IN ONE PLANE AND THE CLOSEST SEPARATION BETWEEN EACH SAID PELLET AND SAID BAR BEING 3/8 INCH OR LESS. 